Patent application number | Description | Published |
20080197916 | Low-Voltage Noise Preventing Circuit Using Abrupt Metal-Insulator Transition Device - Provided are a low-voltage noise preventing circuit using an abrupt metal-insulator transition (MIT) device which can effectively remove a noise signal with a voltage less than a rated signal voltage. The abrupt MIT device is serially connected to the electrical and/or electronic system to be protected from the noise signal, and is subject to abrupt MIT at a predetermined voltage. Accordingly, low-voltage noise can be effectively removed. | 08-21-2008 |
20080297358 | Temperature Sensor Using Abrupt Metal-Insulator Transition (Mit) and Alarm Comprising the Temperature Sensor - Provided are a temperature sensor using a metal-insulator transition (MIT) device subject to abrupt MIT at a specific temperature and an alarm including the temperature sensor. The abrupt MIT device includes an abrupt MIT thin film and at least two electrode thin films that contacts the abrupt MIT thin film. The abrupt MIT device generates abrupt metal-insulator transition at a specific transition temperature. The alarm includes a temperature sensor comprising an abrupt MIT device, and an alarm signaling device serially connected to the temperature sensor. Accordingly, the alarm can be manufactured to have a simple circuit and be of a small size by including the temperature sensor using an abrupt MIT device. | 12-04-2008 |
20090011145 | Method of Manufacturing Vanadium Oxide Thin Film - Provided is a method of manufacturing a large-sized vanadium oxide thin film having a uniform surface, uniform film thickness and stable composition. According to the method, a vanadium-organometallic compound gas is injected into a chamber to form adsorption layer where molecules of the vanadium-organometallic compound are adsorbed on the surface of a substrate. After that, an oxygen precursor is injected into the chamber and thus allowed to accomplish surface-saturation reaction with the adsorbed materials to fabricate a vanadium oxide thin film. | 01-08-2009 |
20090057820 | ABRUPT METAL-INSULATOR TRANSITION DEVICE WITH PARALLEL CONDUCTING LAYERS - An abrupt MIT (metal-insulator transition) device with parallel conducting layers is provided. The abrupt MIT device includes a first electrode disposed on a certain region of a substrate, a second electrode disposed so as to be spaced a predetermined distance apart from the first electrode, and at least one conducting layer electrically connecting the first electrode with the second electrode and having a width that allows the entire region of the conducting layer to be transformed into a metal layer due to an MIT. Due to this configuration, deterioration of the conducting layer, which is typically caused by current flowing through the conducting layer, is less likely to occur. | 03-05-2009 |
20090091003 | INSULATOR UNDERGOING ABRUPT METAL-INSULATOR TRANSITION, METHOD OF MANUFACTURING THE INSULATOR, AND DEVICE USING THE INSULATOR - Provided are an insulator that has an energy band gap of 2 eV or more and undergoes an abrupt MIT without undergoing a structural change, a method of manufacturing the insulator, and a device using the insulator. The insulator is abruptly transitioned from an insulator phase into a metal phase by an energy change between electrons without undergoing a structural change. | 04-09-2009 |
20090114896 | MEMORY DEVICE USING ABRUPT METAL-INSULATOR TRANSITION AND METHOD OF OPERATING THE SAME - Provided are a memory device that undergoes no structural phase change, maintains a uniform thin film, and can perform a high-speed switching operation, and a method of operating the same. The memory device includes a substrate, an abrupt MIT material layer, and a plurality of electrodes. The abrupt MIT material layer is disposed on the substrate and undergoes an abrupt metal-insulator transition by an energy change between electrons. The plurality of electrodes are brought into contact with the abrupt MIT material layer and are melted by heat to form a conductive path on the abrupt MIT material layer. | 05-07-2009 |
20090208639 | METHOD OF FORMING VANADIUM TRIOXIDE THIN FILM SHOWING ABRUPT METAL-INSULATOR TRANSITION - Provided is a method of manufacturing a V | 08-20-2009 |
20090286140 | LITHIUM SECONDARY BATTERY INCLUDING DISCHARGE UNIT - Provided is a lithium secondary battery including a discharge unit capable of delaying or preventing a battery explosion. The lithium secondary battery includes a discharge unit disposed parallel to a battery body. The discharge unit includes a first electrode connected to a positive electrode of the battery body, a second electrode connected to a negative electrode of the battery body, and a discharge material film, disposed between the first electrode and the second electrode, inducing a abrupt discharge above a predetermined temperature. The discharge material film, e.g., a abrupt metal-insulator transition (MIT) material film can induce a abrupt discharge, thereby preventing or delaying a battery explosion. | 11-19-2009 |
20090315724 | PROGRAMMABLE MIT SENSOR USING THE ABRUPT MIT DEVICE, AND ALARM APPARATUS AND SECONDARY BATTERY ANTI-EXPLOSION CIRCUIT INCLUDING THE MIT SENSOR - Provided are an abrupt MIT device with variable MIT temperature or voltage, an MIT sensor using the abrupt MIT device, and an alarm apparatus and a secondary battery anti-explosion circuit including the MIT sensor The MIT device includes an abrupt MIT layer undergoing an abrupt MIT at a transition temperature or a transition voltage and at least two electrode layers contacting the abrupt MIT layer. The transition temperature or the transition voltage varies with at least one of factors including a voltage applied to the electrode layers, a temperature, an electromagnetic wave, a pressure, and a gas concentration that affect the abrupt MIT layer. The MIT sensor is a temperature sensor, an infrared sensor, an image sensor, a pressure sensor, a gas-concentration sensor, or a switch. The alarm apparatus includes the MIT sensor and an alarm-signaling unit connected in series with the MIT sensor. The secondary battery anti-explosion circuit includes a secondary battery, the MIT sensor attached to the secondary battery to sense the temperature of the secondary battery and thus to prevent the possible explosion of the secondary battery, and a protection circuit body powered by the secondary battery. | 12-24-2009 |
20100085126 | OSCILLATION CIRCUIT INCLUDING MIT DEVICE AND METHOD OF ADJUSTING OSCILLATION FREQUENCY OF THE OSCILLATION CIRCUIT - Provided are an MIT device-based oscillation circuit including a power source, an MIT device and a variable resistor, in which a generation of an oscillation and an oscillation frequency are determined according to a voltage applied from the power source and a resistance of the variable resistor, and a method of adjusting the oscillation frequency of the oscillation circuit. The MIT device includes an MIT thin film and an electrode thin film connected to the MIT thin film, and generates a discontinuous MIT at an MIT generation voltage, the variable resistor is connected in series to the MIT device, and the power source applies a voltage or an electric current to the MIT device. The generation of an oscillation and an oscillation frequency are determined according to the voltage applied from the power source and the resistance of the variable resistor. | 04-08-2010 |
20100134936 | CIRCUIT FOR PROTECTING ELECTRICAL AND/OR ELECTRONIC SYSTEM BY USING ABRUPT METAL-INSULATOR TRANSITION DEVICE AND ELECTRICAL AND/OR ELECTRONIC SYSTEM COMPRISING THE CIRCUIT - Provided are an electrical and/or electronic system protecting circuit using an abrupt metal-insulator transition (MIT) device which can effectively remove high-frequency noise with a voltage greater than a rated standard voltage received via a power line or a signal line of an electrical and/or electronic system, and the electrical and/or electronic system including the electrical and/or electronic system protecting circuit. The abrupt MIT device of the electrical and/or electronic system protecting circuit abrupt is connected in parallel to the electrical and/or electronic system to be protected from the noise. The electrical and/or electronic system protecting circuit bypasses toward the abrupt MIT device most of the noise current generated when the voltage greater than the rated standard voltage is applied, thereby protecting the electrical and/or electronic system. | 06-03-2010 |
20100182034 | CIRCUIT FOR CONTINUOUSLY MEASURING DISCONTINUOUS METAL INSULATOR TRANSITION OF MIT ELEMENT AND MIT SENSOR USING THE SAME - Provided are a circuit for continuously measuring a discontinuous metal-insulator transition (MIT) of an MIT element and an MIT sensor using the circuit. The circuit comprises a to-be-measured object unit including the MIT element having a discontinuous MIT occurring at the transition voltage thereof, a power supply unit applying a predetermined pulse current or voltage signal to the to-be-measured object unit, a measurement unit measuring the discontinuous MIT of the MIT element, and a microprocessor controlling the power supply unit and the measurement unit. The discontinuous MIT measurement circuit continuously measures the discontinuous MIT of the MIT element, and thus it can be used as a sensor for sensing a variation in an external factor. | 07-22-2010 |
20100209623 | APPARATUS FOR GROWING LARGE AREA VANADIUM DIOXIDE THIN FILM AND METHOD OF GROWING LARGE AREA OXIDE THIN FILM IN THE APPARATUS - Provided is a technology for in-situ growing a large area VO | 08-19-2010 |
20100213472 | Photo-gating Switch System - A photo-gating switch system comprising a photosensitive device formed on a substrate is provided. The photosensitive device may comprise a photosensitive layer and electrodes formed at both ends of the photosensitive layer. A light source irradiating light to the photosensitive device is integrated beneath the surface of the substrate. | 08-26-2010 |
20100301300 | Three-terminal metal-insulator transition switch, switching system including the same, and method of controlling metal-insulator transition of the same - Provided are a 3-terminal MIT switch which can easily control a discontinuous MIT jump and does not need a conventipnal gate insulating layer, a switching system including the 3-terminal MIT switch, and a method of controlling an MIT of the 3-terminal MIT switch. The 3-terminal MIT switch includes a 2-terminal MIT device, which generates discontinuous MIT in a transition voltage, an inlet electrode ( | 12-02-2010 |
20110006830 | HIGH CURRENT CONTROL CIRCUIT INCLUDING METAL-INSULATOR TRANSITION DEVICE, AND SYSTEM INCLUDING THE HIGH CURRENT CONTROL CIRCUIT - Provided are a high current control circuit including a metal-insulator transition (MIT) device, and a system including the high current control circuit so that a high current can be controlled and switched by the small-size high current control circuit, and a heat generation problem can be solved. The high current control circuit includes the MIT device connected to a current driving device and undergoing an abrupt MIT at a predetermined transition voltage; and a switching control transistor connected between the current driving device and the MIT device and controlling on-off switching of the MIT device. By including the metal-insulator transition (MIT) device, the high current control circuit switches a high current that is input to or output from the current driving device. Also, the MIT device constitutes a MIT-TR composite device with a heat-preventing transistor which prevents heat generation and is connected to the MIT device. | 01-13-2011 |
20110018607 | METHOD AND CIRCUIT FOR CONTROLLING RADIANT HEAT OF TRANSISTOR USING METAL-INSULATOR TRANSITION DEVICE - Provided are a method and circuit for controlling heat generation of a power transistor, in which the power transistor can be protected by preventing heat generation of the power transistor by using a metal-insulator transition (MIT) device that can function as a fuse and can be semi-permanently used. The circuit for controlling heat generation of a transistor includes a metal-insulator transition (MIT) device in which abrupt MIT occurs at a predetermined critical temperature; and a power transistor connected to a driving device and controlling power-supply to the driving device, wherein the MIT device is attached to a surface or heating portion of the transistor and is connected to a base terminal or gate terminal of the transistor or a surrounding circuit from a circuit point of view, and wherein when a temperature of the transistor increases to a temperature equal to or greater than the predetermined critical temperature, the MIT device reduces or shuts off a current of the transistor so as to prevent heat generation of the transistor. | 01-27-2011 |
20110043141 | CIRCUIT FOR PREVENTING SELF-HEATING OF METAL-INSULATOR-TRANSITION (MIT) DEVICE AND METHOD OF FABRICATING INTEGRATED-DEVICE FOR THE SAME CIRCUIT - Provided are a MIT device self-heating preventive-circuit that can solve a self-heating problem of a MIT device and a method of manufacturing a MIT device self-heating preventive-circuit integrated device. The MIT device self-heating preventive-circuit includes a MIT device that generates an abrupt MIT at a temperature equal to or greater than a critical temperature and is connected to a current driving device to control the flow of current in the current driving device, a transistor that is connected to the MIT device to control the self-heating of the MIT device after generating the MIT in the MIT device, and a resistor connected to the MIT device and the transistor. | 02-24-2011 |
20110233616 | GERMANIUM BASED METAL-INSULATOR TRANSITION THIN FILM, METAL-INSULATOR TRANSITION DEVICE INCLUDING THE METAL-INSULATOR TRANSITION THIN FILM, AND METHOD OF FABRICATING THE METAL-INSULATOR TRANSITION DEVICE - Provided are a germanium (Ge) based metal-insulator transition (MIT) thin film which is formed of a Ge single-element material instead of a compound material of two or more elements and by which material growth may be easily performed and a problem of a second phase characteristic in accordance with a structural defect and an included impurity may be solved, an MIT device including the MIT thin film, and a method of fabricating the MIT device. The MIT device includes a substrate; a germanium (Ge) based MIT thin film which is formed of a Ge single-element material on the substrate and in which a discontinuous MIT occurs at a predetermined transition voltage; and at least two thin film electrodes contacting the Ge based MIT thin film, wherein the discontinuous MIT occurs in the Ge based MIT thin film due to a voltage or a current which is applied through the thin film electrodes. | 09-29-2011 |